Adoptive Transfer Of Cytotoxic T Lymphocytes Research Articles

Redirector of Vaccine-induced Effector Responses (RoVER) for specific killing of cellular targets

In individuals with malignancy or HIV-1 infection, antigen-specific cytotoxic T lymphocytes (CTLs) often display an exhausted phenotype with impaired capacity to eliminate the disease. Existing cell-based immunotherapy strategies are often limited by the requirement for adoptive transfer of CTLs. We have developed an immunotherapy technology in which potent CTL responses are generated invivo by vaccination and redirected to eliminate target cells using a bispecific Redirector of Vaccine-induced Effector Responses (RoVER). Following Yellow fever (YF) 17D vaccination of 51 healthy volunteers (NCT04083430), single-epitope YF-specific CTL responses were quantified by tetramer staining and multi-parameter flow cytometry. RoVER-mediated redirection of YF-specific CTLs to kill antigen-expressing Raji-Env cells, autologous CD19+ B cells or CD4+ T cells infected invitro with a full-length HIV-1-eGFP was assessed in cell killing assays. Moreover, secreted IFN-γ, granzyme B, and TNF-α were analyzed by mesoscale multiplex assays. YF-17D vaccination induced strong epitope-specific CTL responses in the study participants. In cell killing assays, RoVER-mediated redirection of YF-specific CTLs to autologous CD19+ B cells or HIV-1-infected CD4+ cells resulted in 58% and 53% killing at effector to target ratio 1:1, respectively. We have developed an immunotherapy technology in which epitope-specific CTLs induced by vaccination can be redirected to kill antigen-expressing target cells by RoVER linking. The RoVER technology is highly specific and can be adapted to recognize various cell surface antigens. Importantly, this technology obviates the need for adoptive transfer of CTLs. This work was funded by the Novo Nordisk Foundation (Hallas Møller NNF10OC0054577).

A modified HLA-A*0201-restricted CTL epitope from human oncoprotein (hPEBP4) induces more efficient antitumor responses.

We previously identified human phosphatidylethanolamine-binding protein 4 (hPEBP4) as an antiapoptotic protein with increased expression levels in breast, ovarian and prostate cancer cells, but low expression levels in normal tissues, which makes hPEBP4 an attractive target for immunotherapy. Here, we developed hPEBP4-derived immunogenic peptides for inducing antigen-specific cytotoxic T lymphocytes (CTLs) targeting breast cancer. A panel of hPEBP4-derived peptides predicted by peptide-MHC-binding algorithms was evaluated to characterize their HLA-A2.1 affinity and immunogenicity. We identified a novel immunogenic peptide, P40-48 (TLFCQGLEV), that was capable of eliciting specific CTL responses in HLA-A2.1/Kb transgenic mice, as well as in peripheral blood lymphocytes from breast cancer patients. Furthermore, amino-acid substitutions in the P40-48 sequence improved its immunogenicity against hPEBP4, a self-antigen, thus circumventing tolerance. We designed peptide analogs by preferred auxiliary HLA-A*0201 anchor residue replacement, which induced CTLs that were crossreactive to the native peptide. Several analogs were able to stably bind to HLA-A*0201 and elicit specific CTL responses better than the native sequence. Importantly, adoptive transfer of CTLs induced by vaccination with two analogs more effectively inhibited tumor growth than the native peptide. These data indicate that peptide analogs with high immunogenicity represent promising candidates for peptide-mediated therapeutic cancer vaccines.

Most Closely HLA-Matched Allogeneic Virus Specific Cytotoxic T-Lymphocytes (CTL) to Treat Persistent Reactivation or Infection With Adenovirus, CMV and EBV After Hemopoietic Stem Cell Transplantation (HSCT)

Adoptive transfer of CTLs can reconstitute antiviral immunity to EBV, CMV and Adv in allogeneic hemopoietic stem cell transplant (HSCT) recipients. However, the time taken to prepare patient-specific products and the lack of virus-specific T-cells in cord blood and seronegative donors restricts application. As part of the NHLBI Specialized Centers for Cell-Based Therapy, we are evaluating in a multicenter setting whether infusion of “off the shelf” closely HLA-matched allogeneic CTLs (CHM-CTLs) will overcome this limitation and prove feasible, safe and effective in HSCT recipients with infection refractory to standard therapy.

Adoptive transfer of pTRP2-specific CTLs expanding by bead-based artificial antigen-presenting cells mediates anti-melanoma response

Cytotoxic CD8 + T cells are key effectors in the immunotherapy of malignant and viral diseases. However, the lack of efficient methods for their in vitro priming and expansion has become a bottleneck to the development of vaccines and adoptive transfer strategies. Synthetic artificial antigen-presenting cells (aAPCs) are now emerging as an attractive tool for eliciting and expanding CTL responses. This study reported a novel approach for targeting malignant melanoma with pTRP2-specific cytotoxic T lymphocytes (CTLs) expanded from the C57BL/6 splenocytes by multiple stimulations with aAPCs made by coating H-2K b-Ig/pTRP2 dimeric complexes, anti-CD28 antibody, 4-1BBL molecules and CD83 molecules to cell-sized latex beads. The induced CTLs exhibited specific lysis against RMA-S cells pulsed with the peptide pTRP2 and H-2K b+ melanoma cells expressing TRP2, while a murine Lewis lung carcinoma cell line 3LL could not be recognized by the CTLs. The peptide-specific activity was inhibited by anti-H-2K b monoclonal antibody Y3. Adoptive Transfer of CTLs specific for malignant melanoma expanding by the aAPCs can mediate effective anti-melanoma response. These results suggested the bead-based aAPCs coated with an MHC-Ig/peptide complex, anti-CD28 antibody, 4-1BBL and CD83 could provide a useful tool for the reproducible expansion of specific CTLs for adoptive immunotherapy.

Preferentially Expressed Antigen of Melanoma (PRAME)-Specific Cytotoxic T-Lymphocytes (CTLs) and Transgenic T Cells To Target Chronic Myelogenous Leukemia (CML).

Following allogeneic hematopoietic stem cell (HSC) transplantation, a graft versus leukemia (GVL) effect mediated by donor T cells contributes to the maintenance of long-term remission. GVL is likely mediated not only by alloreactive T cells, but also by donor lymphocytes recognizing tumor associated antigens overexpressed by leukemic cells. Selective expansion of such tumor-specific CTLs could augment GVL without increasing the risk of graft versus host disease (GVHD). PRAME is a cancer testis antigen (CTA) that is over-expressed by many hematological malignancies, including CML. We therefore generated PRAME-specific CTLs and evaluated their activity against primary CML tumor cells. CD8+ cells from 9 HLA-A*02 healthy donors and 5 CML patients were primed with autologous CD40L-activated B blasts loaded with HLA-A*02 restricted PRAME-peptides in the presence of low concentrations of IL-12, IL-7 and IL-15. Cells were then re-stimulated once a week using an artificial antigen presenting cell line (aAPC), consisting of K562 cell line that was genetically modified to stably express HLA-A*02, CD80 and CD40L and loaded with the same PRAME-peptides. In 8 out of 9 HLA A*02 healthy donors, we expanded (22±7 fold) T cells specific for the ALY-PRAME peptide. Similarly, PRAME-specific CTLs could be expanded from 3 out of 5 CML pts. When assessed by Elispot assay, these CTLs released IFNγ in response to ALY-peptide (511±260 SFC/105 cells) compared to 30±10 IFNγ SFC/105 against an irrelevant peptide. They also lysed autologous-PHA blasts loaded with ALY (84%±12% specific 51Cr release at 20:1 E:T ratio), but not with an irrelevant peptide (<10%). Both IFNγ release and cytotoxic activity were blocked by MHC class I antibodies, indicating that these effects were MHC-restricted. PRAME-specific CTLs also recognized primary CML cells since they produced IFNγ (320±31 SFC/105) in response to CD33+ CML blasts overexpressing PRAME (as assessed by Real Time PCR) isolated from HLA-A*02+ CML patients. Since routine expansion of PRAME-specific CTLs for clinical trials of adoptive T-cell transfer may remain problematic, we next cloned the αβT cell receptor (TCR) from a CTL clone with high affinity for the ALY-peptide (621 IFNγ SCF/105 cells at 0.2 nM peptide). The α- and β-chains were cloned in the SFG retroviral vector using an IRES sequence, and the transgenic αβTCR was expressed in primary T lymphocytes. T cells expressing the transgenic PRAME-specific αβTCR produced IFNγ on exposure to PRAME+ CML blasts (448± 69 IFNγ SFC/105 cells) and killed PHA blasts loaded with the ALY-peptide (42%±7% at 20:1 E:T ratio). In conclusion, our data show that PRAME is a promising target antigen on CML blasts and that adoptive transfer of CTLs or of T cells expressing a transgenic αβTCR targeting this antigen may be of value for patients with the disease.

XIAP targeting sensitizes Hodgkin lymphoma cells for cytolytic T-cell attack

AbstractThe immunosurveillance of Hodgkin lymphoma (HL) by cytotoxic T lymphocytes (CTLs) is insufficient, and the clinical experience with adoptive transfer of CTLs is limited. We have previously reported that defects in mitochondrial apoptotic pathways and elevated XIAP expression confer resistance to different apoptotic stimuli in HL cells. Here, we aimed to develop molecular strategies to overcome the resistance of HL cells against CTL-mediated killing via granzyme B (grzB). In HL cells, grzB-induced mitochondrial release of proapoptotic Smac is blocked, which results in complete abrogation of cytotoxicity mediated by CTLs. Cytosolic expression of recombinant mature Smac enhanced caspase activity induced by grzB and restored the apoptotic response of HL cells. Similarly, down-regulation of XIAP by RNA interference markedly enhanced the susceptibility of HL cells for CTL-mediated cytotoxicity. XIAP gene knockdown sensitized HL cells for killing by antigen-specific CTLs redirected by grafting with a chimeric anti-CD30scFv-CD3zeta immunoreceptor. The results suggest that XIAP targeting by Smac agonists or XIAP-siRNA can be used as a synergistic strategy for cellular immunotherapy of Hodgkin lymphoma.

Establishment of 15 Cancer Cell Lines From Patients With Lung Cancer and the Potential Tools for Immunotherapy

Since lung cancer is the major cause of death not only in Japan but in many other industrialized countries, the development of new therapeutic modalities is quite important. In patients with melanoma, immunotherapy with some tumor antigens has been shown to result in tumor regression. However, little is known about specific immune responses and tumor antigens in lung cancer, due to difficulty in establishing appropriate lung cancer cell lines. In order to resolve these difficulties, we tried to establish and characterize lung cancer cell lines as useful tools for the analysis of tumor-specific immune responses in patients with lung cancer. We tried to establish lung cancer cell lines from 549 patients with resectable lung cancer and from 21 patients with pleural and pericardial effusions or lymph node metastasis. We characterized the established cell lines after the induction of tumor-specific cytotoxic T lymphocytes (CTLs), and analyzed both the major histocompatibility complex (MHC) class I and class II molecules on their surfaces. We succeeded in establishing 15 lung cancer cell lines from 570 specimens (2.6%). The success rate of the establishment of lung cancer cell lines was significantly higher in patients at such advanced stages as MHC III and IV than in those at MHC stages I and II (p = 0.004). MHC class I molecules were expressed in 12 of 15 cell lines (80%), while MHC class II molecules were found in 3 of 15 cell lines (20%) on their cell surfaces by flow cytometry. A haplotype loss of MHC class I antigens was found in 6 of 15 cell lines (40%). Although CTLs were induced in only two of eight cell lines tried by stimulation with nontransduced autologous tumor cell lines, CTLs were successfully induced in all of eight cell lines tested by stimulation with CD80-transfected autologous tumor cells. These results suggested that the tumor antigens recognized by CTLs could thus exist in the tumor cells derived from many lung cancer patients. It is, therefore, possible that antigen-specific immunotherapies may be potentially effective for patients with lung cancer by adoptive transfer of CTLs, as well as by vaccine therapy using tumor-specific antigens.

Rapid Death of Adoptively Transferred T Cells in Acquired Immunodeficiency Syndrome

Human immunodeficiency virus (HIV)-specific cytotoxic T lymphocytes (CTL) probably play the major role in controlling HIV replication. However, the value of adoptive transfer of HIV-specific CTL expanded in vitro to HIV+ patients has been limited: this contrasts with the success of CTL therapy in treating or preventing Epstein-Barr virus and cytomegalovirus disease after bone marrow transplantation (BMT). We investigated the fate of expanded HIV-specific CTL clones in vivo following adoptive transfer to a patient with acquired immunodeficiency syndrome (AIDS). Two autologous CTL clones specific for HIV Gag and Pol were expanded to large numbers (&gt;109) in vitro and infused into an HIV-infected patient whose viral load was rising despite antiretroviral therapy. The fate of one clone was monitored by staining peripheral blood mononuclear cells (PBMCs) with T-cell receptor–specific tetrameric major histocompatibility complex (MHC)-peptide complexes. Although the CTL transfer was well tolerated, there were no significant changes in CD4 and CD8 lymphocyte counts and virus load. By tracking an infused clone using soluble MHC-peptide complexes, we show that cells bearing the Gag-specific T-cell receptors were rapidly eliminated within hours of infusion through apoptosis. Thus, the failure of adoptively transferred HIV-specific CTL to reduce virus load in AIDS may be due to rapid apoptosis of the infused cells, triggered by a number of potential mechanisms. Further trials of adoptive transfer of CTL should take into account the susceptibility of infused cells to in vivo apoptosis.

Gamma interferon production by cytotoxic T lymphocytes is required for resolution of Chlamydia trachomatis infection.

In this study, we used mice in which the gene for gamma interferon (IFN-gamma) has been disrupted (IFN-gamma-/- mice) to study the role of this cytokine in the resolution of Chlamydia trachomatis infection. We show that IFN-gamma-/- mice are impaired in the ability to clear infection with C. trachomatis compared to IFN-gamma+/+ control mice. Activated CD8(+) cytotoxic T lymphocytes (CTL) secrete IFN-gamma in response to intracellular infection, and we have shown previously that a Chlamydia-specific CTL line can reduce C. trachomatis infection when adoptively transferred into infected mice. In the present study, we found that when these IFN-gamma+/+ CTL lines are transferred into Chlamydia-infected IFN-gamma-/- mice, the transferred CTL cannot overcome the immune defect seen in the IFN-gamma-/- mice. We also show that Chlamydia-specific CTL can be cultured from IFN-gamma-deficient mice infected with C. trachomatis; however, the adoptive transfer of IFN-gamma-/- CTL into infected IFN-gamma+/+ mice does not reduce the level of infection. These results suggest that IFN-gamma production by CTL is not sufficient to overcome the defect that IFN-gamma-/- mice have in the resolution of Chlamydia infection, yet IFN-gamma production by CTL is required for the protective effect seen upon adoptive transfer of CTL into IFN-gamma+/+ mice.

Extensive cross-reactivity of adenovirus-specific cytotoxic T cells.

Although adenovirus is a major source of morbidity for immunocompromised individuals and a popular vector for gene therapy, little is known about the cellular immune responses it evokes in humans. Initial trials using adenovirus vectors have been disappointing, probably owing both to a preexisting immune response to Ad2 and Ad5, the most commonly used vector backbones, and to a response to the transgene. The former problem might be overcome by switching from the common type C adenoviruses, of which Ad2 and Ad5 are members, to other less common serotypes. Evidence for the feasibility of this approach has been provided by a rat model system. However, its success in humans depends on there being no immunological cross-reactivity between groups at the humoral or cellular level. Here, we examine the cross-reactivity of the cellular immune response to adenovirus in a human system, and find that human cytotoxic T lymphocytes (CTLs) prepared in vitro against an adenovirus from two of the six subgroups can lyse cells infected with adenoviruses from the other subgroups. Hence, the proposed use of adenovirus vectors from uncommon subgroups to evade memory immune response to subgroup C adenoviruses may not be successful. However, this same cross-reactivity indicates that adoptive transfer of CTLs generated in vitro against one adenovirus serotype may protect immunocompromised patients from infections by adenoviruses of all serotypes.

Adoptive transfer of cytotoxic T lymphocytes induced by CD86-transfected tumor cells suppresses multi-organ metastases of C1300 neuroblastoma in mice.

In this study, we examined the therapeutic antitumor effect of cytotoxic T lymphocytes (CTL) generated against CD86-transfected mouse neuroblastoma C1300. We first generated the transfectant, CD86 + C1300, expressing a high level of mouse CD86 on the cell surface. While CD86 + C1300 cells were rejected in syngeneic A/J mice when inoculated subcutaneously, neither vaccination nor any therapeutic antitumor effect was obtained, implying that C1300 may be a poorly immunogenic tumor. However, in vitro stimulation of splenocytes from either C1300-bearing or CD86 + C1300-rejecting mice with CD86 + C1300 cells resulted in remarkable CTL activity against C1300 cells. The CTL activity induced by CD86 + C1300 was mediated by T cell receptor/CD3 and CD8 and was further enhanced by the addition of interleukin-2. Intravenous inoculation of C1300 cells led to multiple organ metastases including the liver, lung, kidney, ovary, lymph node and bone marrow. To examine the therapeutic effect of CTL in this metastasis model, CTL induced by parental or CD86 + C1300 cells were administrated into C1300-bearing mice. Adoptive transfer of CD86 + C1300-induced CTL resulted in marked elimination of multi-organ metastases and prolonged survival in almost all mice, 70% of which survived indefinitely. These results indicate that adoptive transfer of CTL induced by CD86-transfected tumor cells in vitro would be effective and useful for tumor immunotherapy against poorly immunogenic tumors.